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Ethogram

An ethogram is a systematic catalog or inventory of the observable behaviors exhibited by members of a species, typically compiled as a descriptive list or table that includes definitions, sequences, postures, and contexts for each behavior, serving as a foundational tool in ethology for objectively documenting and analyzing animal action patterns.^[1]^[2] Ethograms are constructed through extended, direct observation of animals in natural or controlled settings, aiming to capture the full repertoire of species-typical actions to enable precise, reproducible behavioral recording and quantification.^[3]^[4] This methodical approach distinguishes ethograms from anecdotal descriptions by emphasizing empirical detail, such as behavioral durations, frequencies, and triggers, which supports causal inferences about the functional and evolutionary significance of behaviors.^[5] In practice, they facilitate comparisons between individuals, groups, or environments, revealing patterns like foraging strategies, social interactions, or responses to stressors.^[6] The utility of ethograms extends to applications in conservation, welfare assessment, and experimental research, where they help distinguish normal from aberrant behaviors, monitor health impacts, and evaluate environmental influences without relying on interpretive bias.^[6]^[7] By providing a standardized behavioral baseline, ethograms underpin broader ethological inquiries into innate versus learned actions and adaptive outcomes, though their completeness depends on the observer's thoroughness and the species' complexity.^[4]^[8]

Definition and Fundamentals

Core Concept and Purpose

An ethogram constitutes a systematic catalog of discrete, observable behaviors exhibited by an organism or species, encompassing precise descriptions of each behavioral unit to ensure unambiguous identification and recording. These behaviors are typically defined in terms of their form, duration, and context, distinguishing them from vague or subjective interpretations to promote reliability in ethological studies.^[9] ^[10] Developed within the framework of ethology, the scientific discipline focused on natural animal behavior, an ethogram serves as the foundational inventory for dissecting complex action patterns into measurable elements, enabling researchers to avoid conflating innate responses with learned adaptations or environmental influences.^[6] The primary purpose of an ethogram is to facilitate objective quantification and analysis of behavior, transforming qualitative observations into data suitable for statistical scrutiny and cross-study comparisons. By standardizing terminology and criteria—such as specifying a "foraging" behavior as involving active search for food items without consumption until located—ethograms minimize observer bias and enhance inter-observer agreement, which studies have shown can exceed 90% reliability when definitions are rigorously applied.^[1] ^[11] This tool underpins causal investigations into behavioral ecology, revealing how innate repertoires interact with ecological pressures, as evidenced in species-specific ethograms for wolves that catalog over 50 distinct postures and vocalizations to track social dynamics.^[5] Ultimately, ethograms advance behavioral biology by providing a replicable lexicon for hypothesis testing, welfare assessments, and conservation efforts, where deviations from baseline catalogs signal stress or habitat disruption; for instance, captive animal ethograms have quantified reduced locomotor diversity in enriched versus barren environments, informing evidence-based interventions.^[11] Their construction demands exhaustive field or lab observation to capture the full repertoire, ensuring completeness without overgeneralization, thus grounding interpretations in empirical patterns rather than anthropomorphic projections.^[3]

Key Components and Classification

An ethogram consists of a systematic catalog of discrete behavioral units for a given species, with each unit defined by objective criteria such as body posture, motor patterns, sensory modalities involved, and contextual triggers to ensure observer reliability.^[10] These definitions distinguish behaviors from one another, often specifying whether a behavior is a state (duration-based, e.g., resting) or event (instantaneous, e.g., grooming onset), and may include sequences or transitions to adjacent actions.^[12] Essential elements also encompass functional annotations, such as the adaptive purpose (e.g., foraging or agonistic), environmental contexts, and quantifiable metrics like frequency, latency, or bout length for empirical analysis.^[1] Behaviors within an ethogram are typically classified into functional or morphological categories to facilitate analysis, such as maintenance (e.g., feeding, resting), locomotion, social interactions, agonistic displays, reproductive activities, and investigatory actions.^[5] This grouping reflects causal linkages to survival needs, with categories designed to be mutually exclusive and exhaustive for comprehensive coverage.^[13] Ethograms themselves may be differentiated as species-specific (comprehensive inventories) versus experimental (tailored subsets for studies), or descriptive (morphology-focused) versus functional (purpose-oriented).^[1] Validation involves inter-observer agreement tests, ensuring classifications align with observable patterns rather than subjective interpretations.^[14]

Historical Development

Origins in Ethology

The systematic cataloging of animal behaviors, foundational to ethograms, emerged within ethology as researchers shifted from anecdotal observations to objective, exhaustive descriptions of species-typical action patterns. Early ornithologists like Charles Otis Whitman advanced this by studying instinctive displays in pigeons during the 1890s, identifying repeatable motor coordinations that formed the basis for later inventories, though without formal terminology. Oskar Heinroth, director of the Berlin Aquarium from 1917, built upon such work by compiling detailed behavioral descriptions for waterfowl and other birds starting in the early 1900s, emphasizing innate, stereotyped sequences observed in captive and wild settings.^[15] Heinroth coined the term "Ethogramm" (ethogram) to denote these catalogs, applying it in studies such as those on the graylag goose and other species, where he documented forms, triggers, and transitions of behaviors to reveal phylogenetic homologies.^[16] This approach prioritized descriptive completeness before interpretive analysis, contrasting with anthropomorphic interpretations common in prior natural history, and enabled comparative ethology by treating behaviors as homologous traits akin to morphological structures. Heinroth's ethograms, often spanning hundreds of entries, highlighted fixed action patterns—stereotyped, releaser-elicited responses—providing empirical data for causal investigations into instinct.^[17] These origins in ethology underscored a commitment to naturalistic observation and first-hand empirical rigor, influencing subsequent pioneers like Konrad Lorenz, who extended Heinroth's methods to imprinting and innate releasing mechanisms in the 1930s. By formalizing behavior as quantifiable units, ethograms facilitated the field's transition from qualitative narration to standardized, verifiable science, essential for testing evolutionary and physiological hypotheses.^[16]

Key Pioneers and Milestones

The systematic cataloging of animal behaviors, foundational to ethograms, emerged from early 20th-century ornithological and ethological studies emphasizing instinctive action patterns. Dutch biologist G.F. Makkink pioneered the explicit use of the term "ethogram" in 1936, publishing An attempt at an ethogram of the European avocet (Recurvirostra avosetta L.) with ethological and psychological remarks, which provided one of the earliest comprehensive inventories of discrete behaviors, including postures, vocalizations, and social interactions, for this shorebird species.^[7]^[18] Konrad Lorenz advanced ethogram-like descriptions through his 1930s fieldwork on greylag geese (Anser anser), documenting fixed action patterns such as greeting ceremonies and threat displays as innate, species-typical sequences triggered by specific stimuli, laying groundwork for causal analyses of behavior.^[19] Niko Tinbergen complemented this in 1951 with The Study of Instinct, which formalized hierarchical models of innate behaviors and included detailed catalogs—proto-ethograms—for species like the three-spined stickleback (Gasterosteus aculeatus), integrating observational data on courtship, aggression, and parental care to distinguish releasing mechanisms from motivational states.^[19] British ethologist Robert Hinde refined ethogram construction in the 1960s, applying quantitative inventories to bird social behaviors, such as chaffinch (Fringilla coelebs) communication and maternal responsiveness in canaries, emphasizing developmental sequences and contextual variability to bridge descriptive catalogs with experimental validation.^[20] A pivotal milestone occurred in 1973, when Lorenz, Tinbergen, and Karl von Frisch received the Nobel Prize in Physiology or Medicine for foundational ethological discoveries, including behavioral repertoires that underscored the role of evolved action patterns in survival and adaptation.^[21] These efforts shifted ethograms from anecdotal lists to standardized tools for hypothesis-testing in comparative biology.

Evolution from Early Observations to Standardization

Early ethologists transitioned from qualitative, anecdotal descriptions of animal behavior—rooted in 19th-century natural history observations by figures such as Charles Darwin and early ornithologists—to systematic inventories of discrete action patterns. Konrad Lorenz, in his studies of greylag geese (Anser anser) during the 1930s, compiled detailed accounts of innate behaviors, including fixed action patterns (FAPs) like triumph ceremonies and displacement activities, which formed the basis of what would later be formalized as ethograms.^[22] These early catalogs emphasized observable, repeatable sequences without interpretive bias, laying groundwork for objective behavioral analysis, though the term "ethogram" itself emerged later, with first recorded uses around 1965–1970.^[2] Similarly, Niko Tinbergen's work on species like the three-spined stickleback (Gasterosteus aculeatus) in the 1940s and 1950s involved exhaustive listings of behaviors, which he described as essential for understanding instinctual mechanisms in The Study of Instinct (1951), marking a shift toward comprehensive, species-specific behavioral repertoires as a foundational step in ethological research. By the mid-20th century, ethograms evolved into structured tools requiring behaviors to be defined as mutually exclusive, objectively observable units to enable reliable inter-observer agreement and quantitative study. This refinement addressed limitations in earlier narrative accounts, incorporating criteria such as discreteness and repeatability, as articulated in methodological discussions from the 1960s onward. Tinbergen explicitly advocated for ethograms as the initial phase of investigation, providing a "dictionary" of behaviors to facilitate causal, functional, developmental, and evolutionary analyses.^[23] However, variability in behavioral descriptions across studies highlighted the need for consistency, prompting calls for standardized formats that prioritized empirical verifiability over subjective interpretation. Efforts toward broader standardization intensified in the 1980s, exemplified by Schleidt et al.'s (1984) proposal for a universal ethogram applicable across species, aiming to create comparable behavioral metrics through predefined categories.^[24] This initiative faced significant resistance, as critics like Drummond (1985) argued that such rigidity overlooked species-specific adaptations and contextual nuances, potentially stifling discovery of novel behaviors.^[24] Consequently, modern practice settled on flexible, validated ethograms tailored to particular taxa or research contexts, with validation through inter-observer reliability tests and iterative refinement based on empirical data, ensuring applicability in fields from ecology to conservation without imposing artificial uniformity.

Methods and Techniques

Observational Protocols

Observational protocols in ethogram construction prioritize systematic, unbiased recording of behaviors to capture natural variability while minimizing observer-induced artifacts. Initial phases often employ ad libitum sampling, where observers freely note all discernible behaviors without temporal constraints, facilitating the identification of a preliminary behavioral repertoire. This approach, though prone to selective bias, serves as a foundational step for cataloging potential ethogram elements before refining definitions.^[25] Subsequent protocols shift to structured sampling to quantify behaviors reliably. Focal animal sampling targets continuous observation of a single individual for predefined durations, typically 10-30 minutes, to record the sequence, duration, and frequency of actions, enabling detailed analysis of individual variation.^[25] Scan sampling, conversely, involves instantaneous snapshots of behaviors across an entire group at fixed intervals (e.g., every 5-15 minutes), which is efficient for assessing prevalence in social species but may overlook brief or sequential events.^[25] All-occurrences sampling records every instance of predefined rare or significant behaviors, such as aggression or mating, regardless of focus animal, to ensure comprehensive capture without omission.^[25] Reliability is enhanced through observer training and validation measures. Protocols mandate habituating subjects to human presence over days or weeks to reduce vigilance or flight responses, with observations conducted from concealed positions or via remote video to approximate natural conditions.^[11] Inter-observer agreement is quantified post-training using metrics like Cohen's kappa, targeting values above 0.80 for behavioral categories, with discrepancies resolved by iterative definition refinement.^[13] Behaviors must be defined operationally—e.g., "foraging" as "manipulating substrate with mouth or forelimbs in search of food"—ensuring mutual exclusivity and exhaustiveness to avoid overlap or unclassifiable actions during coding.^[1] Technological integration supports protocol execution, particularly for elusive species. Continuous video recording allows asynchronous review, timestamping events to precise seconds, and software-assisted coding (e.g., via BORIS or EthoVision) for timestamp accuracy and reduced human error.^[26] In field settings, protocols incorporate environmental controls, such as observing during peak activity periods (e.g., dawn-dusk for diurnal primates) and accounting for factors like weather or group size that influence behavioral expression.^[25] These methods, standardized since foundational work in the 1970s, underpin ethogram validity by balancing breadth with precision, though ongoing calibration against genetic or physiological data is recommended to confirm behavioral authenticity.^[27]

Construction and Validation Processes

The construction of an ethogram typically commences with preliminary ad libitum observations to identify spontaneous behaviors in the focal species, conducted across diverse contexts, times, and conditions to capture variability, often supplemented by video recordings for detailed scrutiny. These observations inform the delineation of discrete behavioral units, described precisely in terms of form (e.g., specific postures or movements), context (e.g., environmental triggers), and metrics such as duration or frequency, adhering to principles like posture-action-environment to ensure objectivity and repeatability. Behaviors are then organized into a hierarchical or categorical structure, aiming for mutual exclusivity—where units do not overlap—and exhaustiveness, encompassing all observable actions without arbitrary omissions, frequently grouped by function (e.g., foraging, agonistic, or affiliative).^[28]^[10] For standardized ethograms applicable across taxa or populations, construction incorporates literature synthesis from prior studies on related species to harmonize terminology and resolve discrepancies, such as distinguishing homologous actions via modifiers for contextual variations. This iterative refinement may involve pilot testing to eliminate ambiguous categories, ensuring the repertoire supports quantitative sampling methods like focal or scan protocols. In species-specific cases, such as primates or felids, over 1,000 hours of footage from controlled enclosures or field sites have yielded 80-100+ validated units, classified into 10-15 functional domains.^[29]^[28] Validation emphasizes inter-observer reliability, where independent coders—often blind to each other—analyze identical recordings or sessions, targeting agreement thresholds like >85% or Cohen's kappa values exceeding 0.8 to confirm consistent application across users. Content and construct validity are assessed via expert panels or consensus methods, verifying that behaviors align with established biological knowledge and predict outcomes like welfare states or ecological roles, sometimes cross-checked against physiological data. Incomplete validation, as in emotion-focused ethograms relying solely on preliminary expert input without field trials, underscores the need for ongoing empirical testing to mitigate observer bias or contextual gaps.^[28]^[30]^[14]

Quantitative Analysis Approaches

Quantitative analysis of ethogram data transforms qualitative behavioral observations into measurable metrics, enabling hypothesis testing on patterns such as activity budgets, transition probabilities, and responses to stimuli. Core approaches include calculating frequencies (occurrences per unit time), durations (total time or bout lengths), and rates (e.g., behaviors per hour), which provide baseline descriptions of repertoire usage.^[31] These metrics are derived from sampling methods like focal animal sampling or scan sampling, where data are aggregated into contingency tables or time-series for further scrutiny.^[32] Time-budget analysis treats behavioral proportions as compositional data, summing to unity, necessitating specialized techniques like log-ratio transformations (e.g., centered log-ratio) to handle dependencies and apply multivariate statistics such as principal component analysis (PCA) or canonical correspondence analysis. This allows visualization of behavioral gradients and inference on environmental correlates, addressing zero-inflation common in sparse ethograms via additive log-ratio methods. For example, PCA on transformed proportions can identify dominant behavioral axes, like foraging vs. resting, facilitating comparisons across individuals or conditions without assuming normality. Sequence analysis quantifies behavioral transitions using matrices of conditional probabilities, often modeled as first-order Markov chains, where stationarity is tested via chi-square goodness-of-fit or likelihood ratio tests. Log-linear models or generalized linear mixed models (GLMMs) extend this to multinomial outcomes, accounting for overdispersion and clustering in repeated observations, as in multilevel multinomial regression for categorical sequences.^[33] These permit detection of non-random patterns, such as stereotyped chains in stress responses, with effect sizes estimated via odds ratios.^[33] Inferential comparisons across groups (e.g., treatments, sexes) employ non-parametric tests like Wilcoxon ranks for small samples or parametric equivalents such as ANOVA on rates, adjusted for multiple comparisons via Bonferroni correction. Reliability of coding is assessed using Cohen's kappa for inter-observer agreement, ensuring metric robustness before broader modeling.^[9] Advanced applications integrate GLMMs with random effects for individual variability, enabling causal inference on predictors like age or habitat.^[33]

Applications in Research and Practice

Behavioral Ecology and Evolutionary Biology

In behavioral ecology, ethograms enable precise quantification of behavioral repertoires to investigate how animals allocate time and energy among activities like foraging, mating, and vigilance, directly linking these to fitness consequences under varying ecological conditions. By defining discrete, observable action patterns, ethograms support analyses of trade-offs, such as the cost of territorial defense versus reproductive investment, which are central to understanding adaptive strategies shaped by natural selection. For instance, ethograms facilitate time-budget assessments that reveal how environmental factors, including resource scarcity or predation pressure, modulate behavior frequencies, thereby testing predictions from optimal foraging theory or life-history optimization models.^[10]^[1] These tools are instrumental in empirical studies of population dynamics and interspecific interactions, where behavioral data from ethograms quantify competitive exclusion or mutualism effects on survival and reproduction. In avian systems, ethograms have documented lekking displays in species like sage grouse, correlating display vigor with mating success and genetic fitness metrics, highlighting sexual selection's role in behavioral evolution. Similarly, in mammalian carnivores, ethogram-based observations of cooperative hunting in packs, such as African wild dogs, demonstrate how synchronized behaviors elevate per capita success rates, influencing group size evolution and kin selection dynamics.^[34]^[35] From an evolutionary biology perspective, comparative ethograms across taxa identify homologous behaviors—stereotyped action patterns shared due to common descent—versus analogous ones arising from convergent adaptation to similar selective pressures. This distinction aids reconstruction of behavioral phylogenies, as seen in analyses of fixed action patterns like egg-rolling in birds, where ethogram data trace developmental and instinctual components back to ancestral forms, informing debates on innateness versus plasticity. Ethograms also underpin quantitative genetics of behavior, enabling heritability estimates for traits like aggression thresholds in fish shoals, which reveal polygenic bases for evolutionary responses to selection. Such applications underscore ethograms' utility in falsifying hypotheses about behavioral conservatism or innovation across lineages.^[34]^[10]

Neuroethology and Comparative Studies

Ethograms play a central role in neuroethology by providing standardized behavioral inventories that enable precise correlations between observable action patterns and underlying neural processes. Researchers use these catalogs to identify discrete behaviors for targeted neurophysiological investigations, such as linking motor sequences to specific neural circuits via electrophysiological recordings or optogenetic manipulations. In model organisms like Drosophila melanogaster, ethograms of courtship and locomotion behaviors have facilitated mappings of sensory-motor transformations to central pattern generators in the nervous system.^[36] For instance, in neurophysiological studies involving rhesus monkeys (Macaca mulatta), ethograms have documented stable behavioral profiles during extended training periods, confirming consistent well-being metrics like locomotion, grooming, and vigilance that align with reliable neural data collection. This approach ensures that behavioral variability does not confound interpretations of brain-behavior relationships, as deviations in ethogram-derived metrics could signal stress-induced alterations in neural responsiveness.^[37] Automated tools, such as DeepEthogram, further advance this integration by applying convolutional neural networks to classify behaviors from video footage, reducing manual annotation time and enabling scalable analysis of neural-behavioral dynamics in freely moving animals.^[38] In comparative studies, ethograms standardize descriptions of behavioral repertoires across species, allowing researchers to discern homologous versus analogous traits and trace evolutionary modifications. By cataloging elemental actions with quantifiable durations and transitions, these tools support phylogenetic reconstructions, as seen in analyses of anuran vocalization displays where shared motor patterns indicate conserved neural substrates despite morphological divergence. High-resolution ethograms derived from synchronized video and accelerometer data have proven reusable for cross-species comparisons, revealing conserved activity bouts in mammals that inform hypotheses about ancestral behavioral states.^[39] Such comparisons highlight causal links between environmental pressures and neural adaptations, prioritizing empirical behavioral data over speculative interpretations.^[40]

Conservation and Wildlife Management

Ethograms enable conservation biologists to catalog species-specific behaviors, establishing normative baselines against which deviations—such as increased vigilance or reduced foraging due to habitat fragmentation—can be quantified to assess anthropogenic impacts.^[41]^[10] In wildlife management, these inventories support the evaluation of population viability by tracking activity budgets and social interactions, informing interventions like protected area zoning or translocation programs where behavioral maladaptation risks population decline.^[42] For critically endangered species, ethograms guide ex-situ efforts; a 2024 study on the Plains-wanderer (Pedionomus torquatus), with fewer than 1,000 individuals remaining in the wild, developed a behavioral catalog to optimize captive rearing and release protocols, emphasizing ground-foraging and anti-predator postures disrupted by agricultural encroachment.^[35] Similarly, ethogram-based monitoring of the vulnerable Hooded vulture (Necrosyrtes monachus) in southern Africa, conducted in 2022, delineated breeding sequences—including nest defense and chick provisioning—revealing heightened stress from pesticide exposure, which informed targeted poisoning mitigation across 15 countries.^[43] In situ applications extend to time-activity budgets for habitat suitability assessments; for example, ethograms of amphibian and reptile species have quantified basking and locomotion patterns to evaluate microhabitat efficacy in restored wetlands, correlating behavioral shifts with survival rates post-reintroduction.^[42] These tools also underpin anti-poaching strategies by identifying behavioral indicators of human proximity, such as elevated flight initiation distances in ungulates, thereby enhancing patrol efficiency in reserves.^[41] Overall, ethograms promote evidence-based management by linking observable actions to ecological pressures, though their efficacy depends on longitudinal data to distinguish transient from chronic perturbations.^[10]

Domestic Animal Behavior and Husbandry

Ethograms serve as essential tools in domestic animal husbandry by cataloging observable behaviors to assess welfare, detect stress or pain, and inform management strategies that align with species-specific needs. In livestock production, they enable farmers and veterinarians to quantify indicators of discomfort, such as tail biting in pigs or stereotypic pacing in confined cattle, facilitating interventions like enriched environments or adjusted stocking densities. For instance, ethograms developed for dairy calves in hutch housing have been used to record social and maintenance behaviors via direct and video observations, revealing patterns that correlate with housing conditions and health outcomes in groups of four animals.^[44] Similarly, in poultry, ethograms measure behaviors like feather pecking or dustbathing to evaluate welfare under different management systems, with no significant behavioral shifts observed in enriched multi-level aviaries compared to controls during handling simulations.^[45] In companion animals, ethograms support behavior modification and veterinary care by defining sequences like predatory motor patterns in dogs or facial expressions in cats indicative of emotional states. For dogs, detailed ethograms of human-animal interactions, including play bows and gaze aversion, aid in training protocols and recognizing handler cues, drawing from observations of recognition factors such as facial and vocal signals.^[46] In felines, standardized ethograms encompassing postures, vocalizations, and locomotion help identify stress responses or unmet needs in household settings, promoting animal-centric husbandry that reduces aggression or withdrawal through targeted environmental adjustments.^[47]^[30] For equines, ethograms have advanced pain detection in ridden horses, where the Ridden Horse Pain Ethogram lists 24 behaviors—such as head tossing or hindlimb stiffness—with thresholds of eight or more indicating likely musculoskeletal issues, validated through blinded assessments correlating scores to veterinary diagnoses.^[48] Broader livestock applications involve semantic analysis of ethograms across species like cattle and sheep to standardize behavioral definitions for automated monitoring, enhancing precision in welfare audits and selective breeding for temperament traits.^[49] These tools underscore causal links between husbandry practices and behavioral outcomes, prioritizing empirical observation over anecdotal reports to mitigate biases in welfare claims from industry or advocacy sources.

Modern Advances and Computational Ethology

Integration with Technology and AI

Advances in computational ethology have integrated ethograms with artificial intelligence and sensor technologies to automate behavioral cataloging and analysis, addressing limitations of manual observation such as subjectivity and scalability. Machine learning pipelines process raw video data or sensor inputs to classify behaviors, generating ethograms with high precision and enabling real-time monitoring across large datasets. For instance, DeepEthogram, released in 2021, employs convolutional neural networks for supervised classification of animal behaviors directly from video pixels, reducing human annotation time while producing reproducible ethograms for species like mice and flies.^[38]^[50] Pose estimation and tracking technologies, powered by deep learning models such as those based on convolutional or transformer architectures, extract kinematic features from video footage to infer ethogram entries, facilitating quantitative analysis of subtle movements. These methods integrate with hardware like high-resolution cameras and inertial measurement units (IMUs) in bio-loggers, allowing ethogram construction from free-ranging animals without continuous human oversight; the Bio-logger Ethogram Benchmark (BEBE), introduced in 2024, standardizes evaluation of such systems using annotated datasets from accelerometers and GPS tags.^[51]^[52] Self-supervised learning approaches further innovate by discovering behavioral motifs without predefined labels, as demonstrated in 2022 work on cetacean vocalizations and movements, where models identify latent patterns akin to ethogram units, enhancing applicability to understudied species.^[53] Integration extends to hybrid systems combining AI with edge computing for field deployment, such as in wildlife monitoring where computer vision algorithms detect ethogram-defined states like foraging or aggression from drone footage. Recent frameworks, including those using transfer learning from pre-trained models, achieve over 90% accuracy in behavior classification for rodents and primates, validated against manual ethograms, though performance varies with data quality and environmental noise.^[54]^[55] These technologies not only accelerate ethogram validation but also link behaviors to physiological correlates via multimodal data fusion, such as synchronizing video-derived ethograms with neural recordings.^[56]

Recent Species-Specific Ethograms

A behavioural ethogram for the critically endangered proboscis monkey (Nasalis larvatus) was developed in 2024 through systematic observation of captive individuals, cataloging 52 distinct behaviours across categories such as locomotion, feeding, and social interactions to support ex-situ conservation strategies amid habitat loss.^[35] This ethogram emphasizes quantifiable metrics, including posture durations and interaction frequencies, derived from over 200 hours of video footage, highlighting the species' arboreal adaptations and affiliative grooming patterns essential for breeding programs.^[35] In 2023, researchers constructed a breeding-season ethogram for the Chinese giant salamander (Andrias davidianus), identifying 28 behaviours including courtship displays like tail-lashing and substrate manipulation, based on continuous monitoring of wild and captive pairs.^[57] The catalog distinguishes agonistic from reproductive actions, with empirical data showing peak activity during nocturnal hours, aiding in captive propagation efforts for this vulnerable amphibian facing overexploitation.^[57] A facial behaviour ethogram for domestic horses (Equus caballus) was published in 2025, documenting 24 discrete expressions such as ear pinning and lip curling, analyzed through frame-by-frame video assessment to infer emotional states and evolutionary homologies with other equids.^[58] Observations from 50 horses under varied stimuli revealed context-specific patterns, with lowered eyebrows correlating to aversion, providing a tool for welfare assessments in equestrian settings.^[58] For laboratory ferrets (Mustela putorius furo), a 2024 ethogram quantified exploratory and well-being indicators in naïve juveniles and adults, encompassing 15 behaviours like scent-marking and object manipulation, validated via timed arena tests yielding inter-observer reliability above 90%.^[59] This framework, grounded in 100+ trials, differentiates stress responses from habituation, facilitating standardized evaluations in biomedical research.^[59] An ethogram for the Atlantic horseshoe crab (Limulus polyphemus) emerged in recent studies, listing spawning and foraging sequences with precise definitions for appendage movements and substrate interactions, drawn from field observations to standardize terminology across populations.^[60] It addresses variability in tidal behaviours, supporting monitoring of declining spawning densities linked to biomedical harvesting.^[60]

Benchmarks and Automated Tools

The Bio-logger Ethogram Benchmark (BEBE), introduced in 2023, provides a standardized dataset collection derived from animal-borne bio-loggers such as accelerometers and magnetometers, featuring behavioral annotations for species including birds, fish, and mammals.^[52] It defines a multi-class classification task to predict behaviors from sensor data streams, with evaluation metrics including accuracy, precision, recall, and F1-scores to assess model performance against ground-truth ethograms. Experiments on BEBE demonstrate that deep learning models, particularly convolutional neural networks adapted for time-series data, achieve up to 85% accuracy in classifying behaviors like foraging or resting in wild animals, outperforming traditional rule-based classifiers.^[52] Efforts in self-supervised learning have proposed benchmarks for automated ethogram discovery without manual annotations, as explored by the Earth Species Project in 2022, which aims to cluster unlabeled animal vocalizations or movement data into putative behavioral units for validation against expert ethograms.^[53] These benchmarks emphasize metrics like silhouette scores for cluster coherence and biological plausibility checks via domain expert review, addressing gaps in supervised datasets limited by labor-intensive labeling.^[53] Automated tools for ethogram construction leverage machine learning to process video or sensor data. DeepEthogram, released in 2021, is an open-source pipeline using supervised convolutional neural networks to detect and timestamp behaviors directly from raw video frames, generating ethograms for lab animals like mice with frame-level precision exceeding 90% after training on annotated clips.^[38] It supports transfer learning from pre-trained models, reducing annotation needs by up to 50% compared to manual scoring.^[50] BORIS software, developed since 2016, facilitates ethogram-based event logging from video or live observations, allowing custom behavioral catalogs with modifiers for states and transitions, and exporting data for statistical analysis in tools like R.^[61] For wild species, inertial sensor fusion with GPS enables automated ethograms via random forest classifiers, as in a 2020 system classifying deer behaviors with 78% accuracy using acceleration patterns.^[62] Recent frameworks like KABR-tools (2025) integrate multi-species ethograms through pose estimation and behavioral labeling on video datasets, supporting scalable analysis across taxa.

Limitations, Criticisms, and Debates

Methodological Challenges

Constructing ethograms requires delineating discrete behavioral units that are mutually exclusive and exhaustive, yet behaviors often grade into one another or depend on context, complicating unambiguous definitions.^[49] This challenge arises because natural behaviors lack sharp boundaries, leading to potential overlaps or omissions in categorization, as noted in validation studies where ethogram reliability hinges on precise, objective descriptions to ensure reproducibility.^[28] Without rigorous criteria like specificity and interpretability, ethograms risk incorporating subjective interpretations that undermine their utility as standardized tools.^[49] Observer bias represents a persistent issue, influenced by factors such as the observer's experience, gender, or preconceptions, which can skew coding of behaviors during live or video analysis.^[63] Experimental tests with species like red-backed salamanders have demonstrated that observer gender affects detection rates of specific actions, highlighting how personal variables introduce variability in ethogram application.^[63] Inter-observer reliability assessments, essential for validation, often reveal discrepancies, necessitating training protocols to minimize such effects, though complete elimination remains elusive even with defined protocols.^[14] Additionally, the mere presence of observers can alter animal behavior, known as the observer effect, which distorts naturalistic data collection in field or enclosure settings.^[64] Sampling methodologies pose further hurdles, particularly for capturing rare or infrequent behaviors, which require extensive observation periods to achieve representative time budgets.^[53] Focal animal sampling or ad libitum recording may miss subtle interactions, while scan sampling risks underestimating durations, leading to incomplete ethograms that fail to reflect full behavioral repertoires.^[11] In species with complex social dynamics, such as primates or livestock, environmental variables and individual variability exacerbate these issues, demanding large sample sizes for statistical robustness, yet resource constraints often limit feasibility.^[65] These constraints underscore the need for hybrid approaches, though traditional manual methods struggle with scalability for voluminous data from modern recording technologies.^[56]

Subjectivity and Standardization Issues

The construction of ethograms inherently involves subjective elements, as researchers must define and categorize behaviors based on observation, which can introduce observer bias and variability in interpretation. For instance, differences in observer experience, gender, or expectations can lead to inconsistent scoring of the same behavioral events, affecting both the reliability and validity of ethogram data.^[63]^[66] Inter-observer reliability testing often reveals marked discrepancies, with studies showing observers agreeing on only about 25% of defined behaviors in species-specific ethograms due to incomplete training or ambiguous definitions.^[66] Complex ethograms exacerbate this, as nuanced distinctions between similar actions (e.g., subtle variations in locomotion or social signals) rely on qualitative judgments that vary across individuals.^[67] Standardization efforts aim to mitigate these issues by promoting consistent behavioral definitions across studies, yet they face significant resistance due to the diversity of species, contexts, and research goals. A 1984 proposal by Schleidt et al. for a universal ethogram applicable to all animals encountered opposition, with critics arguing it oversimplifies context-specific behaviors and ignores evolutionary differences.^[24] While taxon-specific standardized ethograms, such as one developed for felids in 2015, offer practical benefits like improved comparability within groups, broader adoption remains limited by the need for exhaustive, adaptable catalogs that accommodate rare or environment-dependent behaviors.^[68]^[69] Without enforced protocols, ethograms vary widely, hindering meta-analyses and replication; for example, ethogram entries for the same species can differ in granularity, from broad categories (e.g., "foraging") to fine-grained actions, complicating cross-study synthesis.^[70] These challenges underscore the tension between ethograms' utility as objective tools and their dependence on human-mediated classification, prompting calls for hybrid approaches incorporating video analysis or machine learning to reduce subjectivity, though full standardization remains elusive given ethology's emphasis on species-specific realism.^[53]^[56]

Empirical Constraints and Alternative Approaches

Empirical constraints on ethogram construction arise primarily from the labor-intensive nature of direct observation, which often fails to capture rare or context-dependent behaviors despite extended field hours. Traditional ethograms rely on manual cataloging of discrete action patterns, but this approach struggles with inter-observer variability, as definitions of behaviors can differ subtly between researchers, leading to inconsistent classifications across studies.^[24]^[49] Furthermore, ethograms may impose excessive granularity, complicating data processing and interpretation without proportionally enhancing predictive power for underlying motivations or physiological states.^[71] Quantifying subjective elements, such as distress or enrichment engagement, poses additional challenges, as ethograms typically reduce behaviors to observable movements (e.g., walking, grooming) while overlooking qualitative dimensions like valence or intensity, which require supplementary measures for validity.^[72]^[73] Standardization remains elusive due to species-specific variability and environmental influences, with no universal protocols for ethogram development, hindering cross-study comparability.^[49] These limitations are compounded in captive or human-impacted settings, where observer presence can alter natural repertoires, introducing confounds that empirical validation struggles to disentangle.^[65] Alternative approaches mitigate these constraints through computational and integrative methods. Machine learning pipelines, such as DeepEthogram, enable supervised classification of video footage into predefined behaviors, automating ethogram generation and reducing human bias while scaling to large datasets—for instance, achieving high accuracy in rodent pose estimation without manual annotation for every frame.^[38] Qualitative Behavioral Assessment (QBA) offers a complementary framework, using free-choice profiling to capture holistic behavioral expressions via consensus descriptors (e.g., "agitated" or "content"), validated against traditional ethograms in species like sheep and pigs for welfare monitoring.^[74] AI-driven ethology further advances automation via computer vision for real-time behavior recognition in livestock, addressing subjectivity by training models on kinematic data rather than observer-defined categories, though it demands robust initial ethograms for ground-truth labeling.^[49]^[54] These tools prioritize empirical rigor by emphasizing reproducible, data-derived patterns over interpretive catalogs, yet they inherit constraints from training data quality and may undervalue rare events without targeted sampling.^[56]

References

[1]
About Ethograms - Stanford Medicine
An ethogram is a list of species-specific behaviors describing the elements and function of each behavior. It can be a species or experimental list.
[2]
ETHOGRAM Definition & Meaning - Merriam-Webster
a comprehensive list, inventory, or description of the behavior of an organism. Word History. Etymology. etho- (as in ethology) + -gram. First Known Use.
[3]
Ethogram - Biology
An ethogram is a quantitative description of an animal's normal behavior. Constructing a useful ethogram demands time spent watching animals, taking careful ...
[4]
[PDF] Measuring Behavior: Ethograms, Kinematic Diagrams, and Time ...
Ethograms. 3. Ethograms: The most basic data in ethological studies is an ethogram. Classically, ethograms are thought of as a complete encyclopaedia of an.
[5]
Wolf Ethogram | International Wolf Center
An ethogram is a catalog of behaviors exhibited by a species and used to record behavior in a systematic way. It is a vital tool in studying animal behavior.
[6]
Observational ethogram activity
Ethograms are used in the wild to study animals over time to learn what behaviors are typical, which ones may be abnormal, and to monitor the health and ...
[7]
[PDF] An ethogram developed on captive eastern coyotes Canis latrans
As such, ethograms are vital reference material for assessing a study's conclusions (Macdonald et al. 2000).
[8]
Classification of Animal Behavior — Computational Ethology
An Ethogram is a list of behavior descriptions that aims to cover the repertoire of species-typical behavior, typically in the wild.
[9]
An Ethogram to Quantify Operating Room Behavior - PMC - NIH
Ethologists start by creating an “ethogram”—an inventory of carefully defined behavior patterns that can be recognized and reliably documented. Ethograms are ...
[10]
(PDF) The Ethogram and Animal Behavior Research - ResearchGate
The ethogram is an inventory of an animal's behaviour, where any action patterns performed by the animal are listed in an ethogram along with a precise ...
[11]
Monitoring behaviour using an ethogram | NC3Rs
An ethogram is a list of species-specific behaviours, categorised into a table format. When planning to observe animal behaviour, an ethogram is constructed in ...What is an ethogram? · Constructing an ethogram for... · Using the ethogram
[12]
https://files.stlzoo.org/production/documents/RMC/Week-2_Ethogram-Development-Reading.pdf
[13]
Tips for Creating Ethograms - ZooMonitor
Make behaviors mutually exclusive, exhaustive, and objectively defined. Consider broad categories and a standardized master ethogram for consistency.<|separator|>
[14]
Reliability of a descriptive reference ethogram for equitation science
An ethogram and its components, correctly defined behavior units, are the fundamental measuring tools for (applied) ethology and, therefore, also for ...
[15]
Verhaltensbiologie
... Oskar Heinroth (1871-1945), Gründer des Aquariums des Berliner Zoos und ... Ethogramm, bildete die Grundlage für vergleichende phylogenetische. Analysen ...<|separator|>
[16]
[PDF] Konrad Lorenz 1950 The comparative method in studying innate ...
Charles Otis Whitman, who was the first to discover them, called them simply 'Instincts'; Oskar Heinroth, who, ten ... An attempt at an ethogramm of the European ...
[17]
[PDF] nova acta leopoldina - Freie Universität Berlin
... Oskar HEINROTH, worked at the Berlin Zoological Garden, Erwin. STRESEMANN ... Ethogramm der Art bestimmt, hängt aber auch wesentlich davon ab, was er im.
[18]
A Proposal for a Standard Ethogram ... - Wiley Online Library
MAKKINK (1936) used the term Ethogram as a synonym for action system, and with the establishment of ethology as a particular school of thought, ethogram has ...
[19]
[PDF] THE HISTORY AND DEVELOPMENT OF ETHOLOGY
Throughout history aspects of animal behaviour were studied by many naturalists and zoologist. Many thinkers of antiquity, have studied animal behaviour ...
[20]
[PDF] Ethological and experimental approaches to behavior analysis
by Hinde (35) and Altmann (36). The Ethogram. The ethogram is a means by which several behaviors of interestare categorized and operationally defined.Figure ...
[21]
Three Pioneer Observers of Animal Behaviour | Saving Earth
In 1973 the Nobel Prize for Physiology or Medicine was awarded to three pioneer practioners of a new science, ethology—the study of animal behaviour.Missing: ethograms | Show results with:ethograms
[22]
Ethogram from Lorenz (1969), p. 177 - ResearchGate
Download scientific diagram | Ethogram from Lorenz (1969), p. 177 from publication: Epistemological discipline in animal behavior studies: Konrad Lorenz and ...
[23]
[PDF] Tinbergen's four questions: an appreciation and an update
At that time, an aim for ethologists was to provide a complete description of behaviour for a studied species, leading to what was called an ethogram. Since ...
[24]
Towards a Standard Ethogram: Do Ethologists Really Want One?
Aug 6, 2025 · An effort to create a standardized ethogram for all animal species by Schleidt et al. (1984) was met with opposition (see Drummond, 1985; ...
[25]
[PDF] observational study of behavior: sampling methods
INTRODUCTION. This is an observer's guide: in it I will present sampling methods for use. 'in direct observation of spontaneous social behavior in groups of men ...
[26]
Methods and Protocols | Mouse Behavior Ethogram
The ethogram is a list of behaviors by adaptive meaning. Methods include recording home-cage video, and protocols for measuring specific behaviors.
[27]
Observational study of behavior: sampling methods - PubMed
Observational study of behavior: sampling methods. Behaviour. 1974;49(3):227-67. doi: 10.1163/156853974x00534. Author. J Altmann.
[28]
Construction and Validation of a Systematic Ethogram of Macaca ...
These findings systematically document the behavior of M. fascicularis in a free enclosure for use in further investigations.
[29]
A standardized ethogram for the felidae: A tool for behavioral researchers
### Summary of Abstract and Methods for Standardized Felidae Ethogram
[30]
Development of an ethogram/guide for identifying feline emotions
Mar 25, 2021 · This research aimed to develop a straightforward and clear reference guide to feline emotions (ethogram) to aid veterinary professionals in interpreting feline ...
[31]
[PDF] The Ethogram: Quantifying the Behavioral - Juniper Publishers
Sep 27, 2017 · An ethogram is a quantitative description of animal behavior or the behavioral picture. Hence the basic information about animal behavior comes ...
[32]
New approaches to selecting a scan-sampling method for chicken ...
Oct 11, 2023 · The use of the scan-sampling method, especially when a large amount of data is collected, has become widespread in behavioral studies.
[33]
Multinomial analysis of behavior: statistical methods
Aug 25, 2017 · This paper describes a multilevel multinomial behavior model that employs principles of generalized linear mixed models for the analysis of ...
[34]
Ethograms | SpringerLink
Apr 22, 2021 · Ethograms are directories or catalogs of species-typical behaviors. These behaviors, known as action patterns, are discrete, repeatable, identifiable acts.
[35]
Behavioural ethogram to inform ex-situ initiatives for a critically ...
Oct 15, 2024 · An ethogram is a basic tool to the understanding of animal behaviour ... The importance of behavioural studies in conservation biology.Missing: core | Show results with:core
[36]
Computational Neuroethology: A Call to Action - ScienceDirect.com
Oct 9, 2019 · Such representations can vary in form from classical ethograms to low-dimensional plots capturing the trajectory of an animal in space.Missing: ethogram | Show results with:ethogram
[37]
Ethograms indicate stable well-being during prolonged training ...
Ethograms indicate stable well-being during prolonged training phases in rhesus monkeys used in neurophysiological research.
[38]
DeepEthogram, a machine learning pipeline for supervised ... - eLife
Sep 2, 2021 · It uses convolutional neural networks to compute motion, extract features from motion and images, and classify features into behaviors.
[39]
High-resolution ethograms, accelerometer recordings, and ... - Nature
Jan 2, 2024 · Video-recordings and resulting detailed high-resolution behavioral time series are valuable for reuse in comparative studies regarding the ...Background & Summary · Methods · Behavioral Studies
[40]
Ethogram With the Description of a New Behavioral Display for the ...
Apr 27, 2018 · We produced a detailed ethogram for the species and describe a new behavior, the dorsum display, an unknown behavior not reported in any Tropiduridae to date.
[41]
Do You See What I See? Using Ethograms to Observe Animal ...
Mar 1, 2016 · Ethograms have been used by scientists to study a wide variety of organisms: mammals, fishes, amphibians, reptiles, birds, and even protists ( ...<|separator|>
[42]
[PDF] preliminary ethogram and in situ time-activity budget of
Behavioral ecology provides basic data that can be used by conservationists to develop appropriate management strategies for populations (Singh and Kaumanns ...
[43]
Using and ethogram as a guide to understanding Hooded vulture ...
Sep 4, 2022 · An ethogram clearly defines, describes, and classifies distinct behaviours commonly exhibited by a species. Researchers use ethograms as ...
[44]
Development of an ethogram for hutch-housed dairy calves and ...
The ethogram was developed by directly observing the behaviour of ten female dairy calves housed in two group hutches for five days. Based on these observations ...
[45]
Measuring behaviour in hens using an ethogram to assess ... - NIH
Jun 20, 2023 · Results: Use of the ethogram demonstrated no significant difference in hen behaviours in the EMLA group between dummy handling day and treatment ...Missing: livestock | Show results with:livestock
[46]
[PDF] Handout - Ethogram of Dog-Human Interaction
Mar 1, 2008 · There are multiple factors that a domestic animal could use to recognize its human handler including face recognition, speech patterns ...
[47]
[PDF] Ethogram of the Domestic Cat - Uni Vechta
Oct 21, 2024 · A standardised ethogram can help to better understand the needs of cats, to respond to stress or discomfort and to ensure a higher level of ...
[48]
A review of The Ridden Horse pain Ethogram and its potential to ...
The ethogram includes 24 behaviors and it has been proposed that the presence of 8 or more of the 24 behaviors is likely to reflect musculoskeletal pain.
[49]
Foundations of Livestock Behavioral Recognition: Ethogram ... - MDPI
To address the current status of semantically defined definitions in livestock research, this study analyzes livestock behavior ethograms using natural ...
[50]
DeepEthogram, a machine learning pipeline for supervised ... - NIH
DeepEthogram's rapid, automatic, and reproducible labeling of researcher-defined behaviors of interest may accelerate and enhance supervised behavior analysis.
[51]
Beyond observation: Deep learning for animal behavior and ...
This study examines the principles of deep-learning-based tracking, pose estimation, and behavioral analysis, emphasizing their respective strengths, ...
[52]
A benchmark for computational analysis of animal behavior, using ...
Dec 18, 2024 · We present the Bio-logger Ethogram Benchmark (BEBE), a collection of datasets with behavioral annotations, as well as a modeling task and evaluation metrics.
[53]
Self-Supervised Ethogram Discovery - Earth Species Project
Sep 22, 2022 · To understand an animal's behavior, scientists construct an inventory of what types of actions it performs. This inventory, called an 'ethogram' ...Project Summary · In Detail · ImpactsMissing: core | Show results with:core<|control11|><|separator|>
[54]
The quest to develop automated systems for monitoring animal ...
Automated behavior analysis (ABA) strategies are being researched at a rapid rate to detect an array of behaviors across a range of species.
[55]
An Automated AI Framework for Quantitative Measurement of ...
Apr 14, 2025 · With the rapid advancement of deep learning technologies, interdisciplinary computational ethology has employed computer vision algorithms ...2.4 Model Training · 3 Results · 4 Discussion
[56]
Promises and Challenges of Human Computational Ethology - PMC
LINKING ETHOGRAMS AND NEURAL CIRCUITS TO COMPUTATIONAL MODELS ... This technology can also be integrated with augmented reality (AR) headsets ...
[57]
Ethogram of the Chinese Giant Salamander during the Breeding ...
Nov 23, 2023 · The ethogram is the catalog, which is compiled based on the identification and classification of animal behavior. It is a fundamental tool for ...
[58]
An ethogram of facial behaviour in domestic horses - PeerJ
May 28, 2025 · An ethogram of facial behaviour in domestic horses: evolutionary perspectives on form and function. Research Article · Animal Behavior.
[59]
Behavioral assessment of well-being in the naïve laboratory ferret ...
Dec 3, 2024 · This study provides a simple and efficient method to assess psychological well-being and environmental exploration in both juvenile and young adult laboratory ...<|control11|><|separator|>
[60]
[PDF] Ethogram of Limulus polyphemus | Animal Behavior and Cognition
This study presents the first peer-reviewed ethogram of Limulus polyphemus, operationally defining 47 behaviors. Horseshoe crabs were observed in both in ...
[61]
BORIS: a free, versatile open‐source event‐logging software for ...
May 3, 2016 · Being open to user-specific settings, the program allows a project-based ethogram to be defined that can then be shared with collaborators, or ...<|separator|>
[62]
Ethogram-based automatic wild animal monitoring through inertial ...
In this work, an accurate and intelligible framework for automatic remote monitoring of wild animals has been proposed.
[63]
Observer gender and observation bias in animal behaviour research
Aug 8, 2025 · ... observer bias (Branconi et al. 2019, Claassens andHodgson 2017) ... These errors affect both the reliability and validity of an ethogram (Martin ...
[64]
[PDF] Observational Research
How do animals spend their days? Develop a coding system for animal behavior—an ethogram): ... Observer bias because the observer is watching. B. Observer bias ...<|separator|>
[65]
Addressing the Challenges of Conducting Observational Studies in ...
Nov 1, 2017 · Behavioral Observations. Ethograms for handlers, dogs and sheep were developed after consulting those published in previous relevant studies [12] ...
[66]
[PDF] Gaps in Live Inter-Observer Reliability Testing of Animal Behavior
Apr 15, 2021 · We identified that observers were being tested on only approximately 25% of the behaviors listed and defined in the species ethograms. Observers ...
[67]
[PDF] The development and validation of a complex ethogram to ...
The aim of this study was to develop and validate a complex ethogram to describe the behaviour of pigs given access to straw. A 'consensus panel' approach ...
[68]
A standardized ethogram for the felidae: A tool for behavioral ...
Typically, ethograms consist of a list of behaviors exhibited by a species, with corresponding definitions of each using descriptive terms and phrases (Martin ...
[69]
A Standardized Ethogram for the Felidae: A Tool for Behavioral ...
Standardized ethograms offer many practical benefits to behavioral researchers, and several examples exist today for various species and taxa.
[70]
Ethograms | SpringerLink
Sep 20, 2017 · Ethograms are directories or catalogs of species-typical behaviors. These behaviors, known as action patterns, are discrete, repeatable, identifiable acts.<|separator|>
[71]
Back to Actual Behavior – A Modest Proposal on the Example of ...
Jul 18, 2023 · One possible limitation of the ethogram might be its excessive level of detail, requiring a lot of processing work to describe and interpret ...
[72]
[PDF] The Scientific Validity of Subjective Concepts in Models of Animal ...
Standard methods of measurement ('ethograms') categorise behaviour in terms of discrete, quantifiable states of physical movement (e.g. walk, sit, chew, sniff).
[73]
An Evaluation of Ethograms Measuring Distinct Features of ... - MDPI
Aug 10, 2022 · Ethogram Efficacy. In general, we found that our ethograms were effective in capturing the range of enrichment objects, manipulation behaviors, ...
[74]
Evaluating Qualitative Behavioral Assessment and Ethogram ...
Quantitative behavioral assessments using predefined ethograms for species' behaviors are utilized to determine the variety, and frequency, of different ...Missing: ethology | Show results with:ethology